DE4002013A1 - System for adjusting output of charging units for image prodn. - includes unit for charging light responsive or photo-conductor drum and discharge lamp which clears charge produced on drum - Google Patents

Abstract

A unit (30) is provided for the designation or the selection of the output power setting of the charging unit (12). A unit (21) detects a signal, if the output setting of the charging unit is designated or elected by the designation or selection unit, which flows from the image reception element (11). A unit (23) is provided for adjusting the output power of the charging unit, until the output value reaches a predetermined value. Two drive units (19,27) are provided respectively for driving the image reception element in a given direction and for moving the developing unit (13) in one direction from the image reception element (11).

Description

The invention relates to an image forming device, like an electronic copier, with z. B. a light sensitive drum or photoconductor drum, and be particularly hits a device for adjustment an output power from around the drum orderly chargers.

In an image forming apparatus with a photoconductor Drum is the size of the load on the drum each drum used differently, even if on a charger is applied the same voltage. It is therefore necessary to switch off the respective drum power outputs of a charger for catchy charging (pre-charging), a charger for image transmission and a charger for Sheet separation that is around the photoconductor drum are arranged to regulate or adjust.

For setting the output powers this around it is the charger arranged around the drum usual practice, a supply voltage to the charging units according to a surface potential, the using a surface electrometer on the surface or lateral surface of the photoconductor drum measured will regulate. However, it is not advisable to do this Arrange the surface electrometer in the copier because this thereby receives larger dimensions and costs becomes more complex.  

One possibility is to avoid the above disadvantage ability to regulate the output of charging units using a measuring device or Trom mel replica (jig) has been developed. If the out output of the charging units regulated or a to be placed are the photoconductor drum removed from the copier and attached to the appropriate Place an aluminum measuring device or replica a similar shape. At this measuring device then a corona discharge and a current or voltage received from the measuring device size to match a predetermined size measured. One becomes a high voltage trans formator connected to the charger, parallel connected variable or variable resistance of Hand set. The manual adjustment operation under Use of the measuring device mentioned has, however compared to one actually on the photoconductor Drum running setting as difficult and too proven to be time consuming.

Because the size of the photoconductor drum from device to device is different, several measuring devices (jigs) provided according to the respective drum size and be exchanged accordingly. This makes the setting cumbersome and tedious.

The object of the invention is therefore to create a Chargers featured in an imaging device output control or adjustment device with the help of the setting (control) a photoconductor drum perfectly and automatically can be carried out in a short time without the drum by an appropriate measuring device or afterimage needs to be replaced.  

This object is achieved with a device for adjustment an output power of chargers at one Imaging device with a charger for construction a charge on an image receiving element and one discharge unit arranged on the image receiving element solved by the invention for removing the charge a unit for designating or selecting the starting line Charger power setting, one unit to then when the output power setting of charging unit by means of the labeling or dialing unit draws or is selected to detect a signal, that with charging and discharging by charger or discharge unit flows from the image receiving element, and a unit for setting an output power (output) of the charger until its output power reaches a predetermined size.

According to the invention, the output power setting the charging unit (s) directly on the image receiving element ment (drum) and without the need for a spe zielle measuring device or replica properly before be taken. This setting can be done in a short time, d. H. done quickly without the image receiving element replace with a corresponding special replica to have to.

This setting can also be made by making an ent descriptive name or choice (designation) by means of a labeling unit automatically.

The output power setting on the charger ten can be done very precisely because in the case of loading drawing or choice using the designation unit Development unit and the cleaning unit by the Drive unit moves away from the image receiving element the.

The following are preferred embodiments of the Er Finding explained in more detail with reference to the drawing. It shows gene:

Fig. 1 is a block diagram of a main part of an apparatus according to an embodiment of the invention,

FIG. 2 shows a block diagram of a current measuring circuit in the device according to FIG. 1, FIG.

Fig. 3 is a flowchart for explaining the Functioning of the device according to Fig. 1,

Fig. 4 is a characteristic diagram of the relationship of a current quantity with respect to a photosensitive or photoconductor drum and the output quantity of a D / A converter and

Fig. 5 is a block diagram of a main part of a device according to a second embodiment of the invention.

Fig. 1 shows a main part of an electronic Ko piergeräts to which the invention is applied.

Around a photoconductor drum 11 are an initial charge (precharge) serving, the drum 11 charging charge 12 , a development unit 13 for applying a developer to an electrostatic latent image generated on the drum for the purpose of developing the same into a visible image , a transfer charger 14 for transferring the visible (toner) image onto a paper sheet, a separation charger 15 for electrically (electrostatically) separating the paper sheet to which the visible image has been transferred by the transfer charger from the drum 11 , one Trennklin ge 16 to mechanically separate the electrically separated paper sheet from the drum 11 by the separation charging unit 15 , a cleaning unit 17 for cleaning the outer surface of the drum 11 of residual developer remaining on it and a discharge lamp 18 for loading the residual charge on the drum 11 arranged.

The (photosensitive or photoconductor) drum 11 is rotated by a motor 19 around a conductive support 20 as a reference in the direction of the arrow in FIG . With the conductive substrate 20, a current meter 21 is electrically connected to a conductive via the carrier 20 to ground FG of the drum 11 (Fig. 2) to detect current flowing respectively in the setting of the charger 12 to be measured.

Referring to FIG. 2, the current measuring unit 21 comprises a Paral lelschaltung of a capacitor C and a thrust resistance R which is connected between the conductive support 20 and ground, a buffer amplifier 21 A for amplifying a voltage generated in accordance with a current flowing through the resistor R current, a full-wave rectifier circuit 21 B for full-wave rectification of an output voltage of the buffer amplifier 21 A and a smoothing circuit 21 c for smoothing an output voltage from the full-wave rectifier circuit.

The output of the current measuring unit 21 is closed according to FIG. 1 via an A / D converter 22 to a control unit 23 .

To the control unit 23 , which controls the entire copier, z. B. a lamp control unit 24 , a D / A converter 25 , a motor driver unit 26 , a development unit drive part 27 , Solenoidtreiberein units 28 and 29 , a control panel 30 , a memory 31 , a heating element 32 of a fixing unit, not shown, and a blower motor 33 for driving a fan that circulates air in the copier, sen ruled.

The lamp control unit 24 serves to regulate or control the lighting of the discharge lamp 18 .

The D / A converter 25 converts a digital signal supplied by the control unit 23 into an analog signal and delivers this to a high-voltage transformer 34 , which in turn corresponds to a predetermined current (s) in accordance with the analog signal from the D / A converter 25 or voltage of the charging unit 12 .

The development unit drive part 27 is able to move the development unit 13 into and out of contact with the (light-sensitive) drum 11 .

The solenoid driver unit 28 drives a solenoid 35 , which in turn rotates the separating blade 16 .

The solenoid driver unit 29 drives a cleaning unit 17 constituting solenoid 36 which moves a cleaning blade 37 into and out of contact with the drum surface 11 .

The control panel 30 contains e.g. For example, a copy key (to be described) 30 A to initiate a copying operation, ten keys 30 B for setting the number of copy paper used leaves or the number of copies to and a Ausgangsleistungseinstellmodus and the like. For the charger and a display unit 30 C for displaying the number of copies entered by the decimal keys 30 B and the like.

The memory 31 contains e.g. B. an output power setting for the charger and a program for determining the operation of the control unit 23rd

The output power setting on the charging unit in the arrangement described is explained below with reference to FIG. 3.

After inputting the output setting code of the charger by means of the decimal keys 30 B on the operation panel 30 , the control unit 23 sets an output setting mode with respect to the charger. Upon receipt of an output setting code, the control unit 23 performs the operation of FIG. 3.

First, an output power setting mode is displayed on the display unit 30 C of the operation panel 30 (step ST 1 ). In this state, the developing unit 13 is moved away from the drum 11 by its driving part 27 , and the solenoids 35 and 36 are driven by the solenoid driving units 28 and 29 , respectively, to move the separating blade 16 and the cleaning blade 37 away from the drum 11 (step ST 2 ). The heating element 32 of the fusing unit is switched off, as is the fan motor 33 (step ST 2 ).

The motor 19 is controlled by the motor driver unit 26 (step ST 3 ). Reference data stored in advance in memory 31 are fed by the control unit 23 to the D / A converter 25 , which converts this into an analog signal upon receipt of the reference data, which in turn is fed to the high-voltage transformer 34 . This means that the transformer 34 is operated in accordance with a predetermined analog signal in order to generate a charge on the surface of the (photoconductor) drum 11 through the charging unit 12 . At the same time, the discharge lamp 18 is lit up by the lamp control unit 24 , ie switched on. In this way, a corona discharge step (ie, corona discharge charging) and a discharge step are sequentially carried out (step ST 4 ).

Furthermore, a current flowing from the drum 11 to ground FG via the conductive carrier 20 (or a current from the carrier 20 to the drum 11 in the case of a charge of opposite polarity) is measured by the current measuring unit 21 , the output signal of which is via the A / D converter 22 is fed to the control unit 23 (step ST 5 ). The control unit 23 compares the measured value with the reference value previously stored in the memory 31 (steps ST 6 , 7 ). If the measured value lies outside an allowable (tolerance) range of the reference value, the control unit 23 supplies z. B. a digital variable "128" as a controlled variable to the D / A converter 25 (step ST 8 ). The latter generates a setting or control current (or a setting or control voltage) corresponding to the digital variable and delivers this (these) to the high-voltage transformer 34 . Upon receipt of an output signal from the transformer 34 , the charging unit 12 in turn performs a (n) corona discharge (step). Steps ST 5 to ST 7 are carried out in this way.

The corona discharge and the discharge step are carried out sequentially by the charging unit 12 and the discharge lamp 18 , respectively, a current flowing from the drum 11 being measured by the current measuring unit 21 . The measured value is compared by the control unit 23 with the reference or reference value. The control unit 23 provides z. B. a digital variable "192" as a controlled variable if the measured value is smaller than the reference value, and a digital variable "64" as a controlled variable if the measured value is larger than the reference value. In this way, steps ST 5 to ST 8 are carried out, ie processed.

As a result, the controlled variable is sequential according to the requirement a difference or deviation between the measured value and Reference value set and thus in the permissible (Tolerance) range of the reference value.

FIG. 4 shows a graphical representation of the relationship of a current fed to three different photoconductor drums to an output variable of the D / A converter 25 .

If the measured value is within the permissible range of the reference value (step ST 7 ), the control variable obtained is stored in the memory 31 (step ST 9 ). The high voltage transformer 34 and the discharge lamp 18 are turned off just like the motor 19 , whereupon an output setting operation is completed (steps ST 10 and 11 ).

Then, when a normal copying operation is to be performed, a charging output of the charging unit 12 is set based on the control size available at the end of the control cycle.

In the device according to the invention, the off Power output setting on the (existing) photo  conductor drum. Since here the previously used measuring device or replica is not needed, can when charging output power setting replacing the drum with this measuring device Direction or replication are omitted. In addition, one Charge or charge size in one of the photoconductor Drum adapted in actual operation be put, so that an exact setting is ensured.

When the control unit 23 is set in an output setting mode, the developing unit 13 , the separating blade 16 and the cleaning blade 37 are moved away from the drum 11 , and the heating element 32 of the fixing unit is switched off, so that the blower motor 33 is also kept on. Here, when the drum 11 is rotated in the setting of the output of the charger, it is possible to have a setting error caused by the toner from the developing unit 13 , twisting of the cleaning blade 37, and a change caused by the fixing unit and the blower to avoid the ambient temperature in the copier. As a result, an accurate output setting can be made.

By setting the control unit 23 in the output power setting mode, an automatic output power setting can take place; This eliminates the need for manual adjustment of a control resistor connected in parallel with the high-voltage transformer in accordance with the measurement result, as is necessary in the prior art. This setting can thus be easily carried out in a short time without affecting with a human factor, such as setting by an operator, from deviation.

The control variable determined during the setting process is stored in the memory 31 and used as a setting or control variable for the next setting process in order to initiate the setting. Since the setting can thus be carried out with a smaller setting error (control deviation) between the controlled variable and the reference value, the required setting time can be reduced accordingly.

Fig. 5 shows a second embodiment of the invention.

While in the previously described embodiment a current flowing from the photoconductor drum 11 is measured by the current measuring unit 21 , in the embodiment according to FIG. 5 a voltage applied to the drum 11 can be measured by means of a voltage measuring unit 40 and by an A / D converter 22 are converted into a digital signal to be fed to the control unit 23 .

With this configuration, the same advantage as achieved with the previously described embodiment.

Although the setting in connection with the charger 12 has been described above, the invention is not limited to this embodiment, but an output power setting on the transfer and separation charger may also be made. The respective charging units can each be set so that they are put into operation sequentially and a current flowing to and from the photoconductor drum 11 is measured. This setting can be made sequentially and automatically in the order given in FIG. 1 or FIG. 3 or by the operator by designating or selecting the steps. be carried out individually on the control panel.

Claims (7)

1. An apparatus for setting an output power of charging units in an image forming apparatus
a charging unit ( 12 ) for building up a charge on an image receiving element ( 11 ) and
a discharge unit ( 18 ) arranged on the image receiving element for removing the charge, characterized by
a unit ( 30 ) for designating or selecting the output power setting of the charging unit ( 12 ),
a unit ( 21 ) for detecting when the output line setting of the charging unit ( 12 ) is designated or selected by means of the designation or selection unit ( 30 ) to detect a signal which is generated during charging and discharging by the charging unit or discharge unit from the image receiving element ( 11 ) flows, and
a unit ( 23 ) for setting an output power (output) of the charging unit ( 12 ) until its output power reaches a predetermined size. 2. Device according to claim 1, characterized by
a first drive unit ( 19 ) for driving the image receiving element in the given direction,
a unit ( 13 ) for developing an electrostatic latent image formed on the image receiving element ( 11 ) by means of a developer,
a unit ( 37 ) for removing the developer deposited on the image receiving member ( 11 ),
a second drive unit ( 27 ) which, when the output setting on the charger ( 12 ) is selected by means of the designating or selecting unit, drives the developing unit ( 13 ) in a direction away from the image receiving member, and
a third drive unit ( 36 ) which, when the output setting on the charging unit ( 12 ) is selected by means of the labeling or selection unit, drives the cleaning unit ( 37 ) in one direction away from the image receiving element ( 11 ). 3. Apparatus according to claim 1, characterized in that the control unit ( 23 ) compares a detection or measurement output signal from the detection unit ( 21 ) with a reference value and a signal accordingly a difference or deviation therebetween, and that a unit ( 25 ) for generating a signal fed to the charging unit ( 12 ) corresponding to the signal size generated by the setting unit ( 25 ) and a unit for storing the reference value are provided. 4. The device according to claim 3, characterized in that the generating unit ( 25 ) comprises a unit for converting the reference value representing a digital signal into an analog signal. 5. The device according to claim 3, characterized in that the detection unit ( 21 ) comprises:
Elements ( R , 21 A ) for converting a current flowing from the image receiving element ( 11 ) into a voltage,
an element ( 21 B ) for rectifying the voltage output by the converter elements ( R , 21 A ) and
an element ( 21 C ) for smoothing an output voltage of the rectifier element ( 21 B ). 6. The device according to claim 2, characterized in that the labeling or dialing unit ( 30 ) decimal keys for setting the number of copy (paper) scroll or (to be produced) copies. 7. The device according to claim 2, characterized in that the first drive unit ( 19 ) consist of a motor and the third drive unit ( 36 ) consist of a brine noid.